Electron-phonon coupling in photoemission spectra

Hengsberger, Matthias; Frésard, Raymond; Purdie, D.; Segovia, P.; Baer, Y.

doi:10.1103/physrevb.60.10796

Cited by 84 publications

(70 citation statements)

References 26 publications

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“…Moreover, they demonstrate that all necessary parameters can be extracted from the experiment: l ¼ 1:18 and ho m ¼ 70 meV. Also a contribution of G def ¼ 75 meV is found, which translates into a mean free path of about 15 Å in the surface plane [142]. This value appears independent of E i , at least up to a distance of 0.6 eV from E F .…”

Section: Other Materialsmentioning

confidence: 65%

“…For more details on theory and the interpretation of Im S concerning the G surface states on noble metals see Section 6.1. An even larger contribution of S is to be expected for the surfaces of Be, where ho m ¼ 70 meV and the coupling parameter l on Be(0 0 0 1) is estimated between 0:7 AE 0:1 [126], 1.15 [140] and 1.18 [141,142]. Strong contribution to G ep is indeed observed and will be discussed in the following.…”

Section: Other Materialsmentioning

confidence: 92%

“…They determine the initial state energy E i ¼ À2:73 eV at G, and effective masses m Ã =m ¼ 1:19 (along GM) and m Ã =m ¼ 1:14 (GK). Hengsberger et al [141,142] demonstrated that the surface state is drastically modified near E F by the electron-phonon interaction. In particular, the lineshape near E F is no longer a Lorentzian: as the surface state approaches E F , a second peak appears at E i % À70 meV.…”

Section: Other Materialsmentioning

confidence: 99%

“…to the noble metals. Very highresolution lineshape results on the G surface state were presented first by Hengsberger et al [141,142], with data taken at T ¼ 12 K and resolution parameters DE ¼ 5 meV and Dy ¼ 0:2 (in the direction of strong dispersion), respectively. They determine the initial state energy E i ¼ À2:73 eV at G, and effective masses m Ã =m ¼ 1:19 (along GM) and m Ã =m ¼ 1:14 (GK).…”

Section: Other Materialsmentioning

confidence: 99%

“…The second quasiparticle peak is caused by the strong electron-phonon coupling. Using conventional many-body theory Hengsberger et al [142] describe precisely this exceptional double-peak evolution of the experimental spectra. Moreover, they demonstrate that all necessary parameters can be extracted from the experiment: l ¼ 1:18 and ho m ¼ 70 meV.…”

Section: Other Materialsmentioning

confidence: 99%

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Electron–Phonon Interaction at Interfaces

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Many-body effects and their interplay are at the heart of some of the most interesting problems in condensed matter physics, and frequently the simultaneous presence of different effects is found in complex materials. The electron-phonon (eÀph) interaction is one such effect that limits the lifetime of excited electrons (or holes) and has long been studied because of its role in many phenomena, from electrical conductivity to electronic heat capacity and BCS-type superconductivity. Several experimental techniques such as tunneling spectroscopy or heat capacity measurements have provided information on the electron-phonon coupling strength averaged over the bulk Fermi surface of metals [1].Experimentally, recent advances in angle-resolved photoemission (ARPES) have opened the opportunity for a study of many-body effects in unprecedented detail. Most importantly, studies are not confined to averages over the Fermi surface but detailed information about the energy and k-dependence of the interaction has come within reach. This permits, for instance, to establish the symmetry of the superconducting gap in novel superconductors [2,3].The eÀph interaction stands out as a fundamental many-body process that can be tested by both experimental and theoretical methods. Much has been learned by studying the eÀph coupling on carefully chosen electronic surface states, for which good arguments can be made for the eÀph interaction to be the only many-body effect giving rise to a bosonic spectroscopic signature. Surface states have also played an important role because they have, as do the states in the cuprates, a merely two-dimensional dispersion, an essential prerequisite for the analysis of ARPES data.In the most simple picture, the eÀph coupling changes the dispersion and the lifetime of the electronic states in a material. This situation is illustrated in Figure 7.1a. Very close to the Fermi level, within a typical phonon energy hv D , the dispersion is renormalized such that it is flatter at the Fermi energy. Consequently, the effective mass of the electrons at the Fermi level and the density of states are

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Electron Based Methods: 3.2.2 Photoelectron Spectroscopy and Diffraction

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2013

Surface and Interface Science

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Electron-phonon coupling in photoemission spectra

Cited by 84 publications

References 26 publications

Decay of electronic excitations at metal surfaces

Decay of electronic excitations at metal surfaces

Electron–Phonon Interaction at Interfaces

Electron Based Methods: 3.2.2 Photoelectron Spectroscopy and Diffraction

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